AT17524U1 - Communication module and lighting bus system with network interface - Google Patents

Abstract

The present invention relates to a communication module for connecting a lighting bus system (1) to a network (3) based on an Internet protocol, with each component (2a .. 2f) coupled to the bus system (1) being assigned a unique bus address, the communication module (4) several network addresses are assigned, at least one of the several network addresses contains the bus address of a component (2a .. 2f) and the communication module (4) is designed to receive data from the network (3) sent to the at least one network address, to extract the bus address of the component (2a .. 2f) from the network address, to determine data to be sent to the component (2a .. 2f) with the extracted bus address on the basis of the received data and to transmit the determined data to the component (2a .. 2f). . 2f) with the extracted bus address via the bus system (1), or generated autonomously by a component (2a .. 2f) and sent to the To provide communication module (4) sent data over the network (3) at least one network subscriber.

Description

description

COMMUNICATION MODULE AND LIGHTING BUS SYSTEM WITH NETWORK INTERFACE

The present invention relates to a communication module, a lighting bus system and a method for connecting a lighting bus system to a network based on the Internet Protocol.

In building technology, lighting systems can have components such as sensors, lights, operating devices, actuators, switches and dimmers, which are connected to one another via a bus system.

In a lighting system according to the DALI industry standard (Digital Addressable Lighting Interface), a randomly generated one for each component or each bus user, and then with the help of which a permanently assigned address for the control in the bus system can be generated. Each bus participant or each component can be addressed with his/her address in the bus system and can send and receive control commands and/or status information within the bus system.

WO 2016/065382 A1 discloses a bus system to which a plurality of operating devices and a control device for controlling the operating devices are coupled, the control device being coupled to a network based on the internet protocol and receiving the control commands for the operating devices from this network.

However, WO 2016/065382 A1 does not disclose how the control commands are assigned to the respective operating device or the respective bus address is determined, which is necessary for individual control of the operating devices. In addition, information on the current operating status, the configuration or properties of the operating devices is often required for the generation of control commands, which information must be queried from the operating devices via the network.

The invention is based on the object of specifying devices and methods which reduce the problems described. In particular, the object is to provide a communication module, a lighting system and a method with which a lighting bus system can be connected to a network based on an Internet protocol for the transmission or querying of data in a simple and cost-effective manner.

[0007] This object is solved according to the features of the independent claims. The invention is further developed by the features of the dependent claims.

According to the present invention, each component coupled to the bus system is assigned a unique bus address (component ID) and the communication module is assigned a plurality of network addresses, with at least one of the plurality of network addresses containing the bus address (component ID) of a component and the communication module being designed for this purpose is to receive data from the network sent to the at least one network address, to extract the bus address of the component from the network address, to determine data to be sent to the component with the extracted bus address on the basis of the received data and to send the determined data to the component with the extracted bus address via the bus system.

Thus, the data received from the network can be assigned to a component of the bus system in a simple manner. There is no need to determine the bus address based on, for example, the type of control command or query.

Alternatively or additionally, the communication module can be configured to make the data (control commands, status reports) generated autonomously by a component and sent to the communication module available to at least one network subscriber via the network. The transmission of the data (control commands, status messages) to the power supply

subscriber can take place immediately after the receipt of this data in the communication module or at the request of the network subscriber. For this purpose, the communication module can determine the network address of the network subscriber from the data received from the network subscriber or using a table which assigns at least one network address of a network subscriber to the bus address of the component and/or the control command/status message.

The components coupled to the bus can be sensors, lights, operating devices, actuators, switches and/or dimmers, which transmit control and/or status information via the bus.

The communication module can be designed to extract the address of the component from the interface identifier of the network address based on Internet Protocol Version 6, with the bus address being inserted at a specific point in the network address known to the communication module or replaced by specific characters in of the network address may be marked.

In the bus system, several components can be addressable by means of a group bus address, the communication module being designed to determine the group bus address on the basis of a multicast address contained in the network address and data transmission to the determined group Perform bus address related components based on the received data.

Alternatively or additionally, the communication module can be configured to determine a control command from the received data and to send the determined control command to the component with the extracted bus address or the components with the determined group bus address. The control command can be contained in the network address or in another part of the received data and can be an on, off, dimming, position or configuration command. In this way, it is possible to remotely control a light or roller shutter with a mobile device (which can also be a smartphone) connected to the network, for example.

Alternatively or additionally, the communication module can be configured to perform a conversion of the data packet format of the received data into the data packet format of the bus system as a transparent gateway, at least from the point of view of the network. This allows the connection of several bus systems, each having a communication module, via the network.

Alternatively or additionally, at least one property of at least one component that can be queried in the bus system can represent a resource that is accessible via the network and can be reached via a URL, the communication module being designed to do this when the received data is a request (with a hypertext Transmission protocol HTTP or another protocol such as UDS, FTP, SMTP, POP, Telnet, OPC UA) of the resource contain the property of the component assigned to the requested resource in a translation table or a bus command for querying or setting this property determine and query this property in the data transmission.

It is thus possible in the Internet of Things (IoT; IoT: Internet of Things) to address bus components like any other IoT device via a URL address and to control them with the same methods and commands. Some or all properties of the components, such as the controllability of the light intensity or color temperature, can be accessed as resources from the network.

In addition, the communication module can be designed to generate one or more data packets with information received from the component regarding the queried property, to determine a network address for the transmission of these data packets on the basis of the received data, and to send the data packets to the determined network address to send. The communication module can generate an XML document or another document with the information received from the component and send it to the determined network address in response to the queried property/resource.

Alternatively or additionally, a translation table or a table entry can be assigned to each component with at least one resource that can be queried, the communication module being designed to use the bus address (component ID) contained in the network address to determine the respective translation To determine the table or the corresponding table entry for determining the property to be queried.

The bus system can be a DALI bus, in which at least one component can send a message referred to as "DALI Event Message" via the bus system, the "DALI Event Message" data being the above of one Component correspond to autonomously generated data and the "DALI event message" in the table is assigned a "callback URL" as an address to which the "DALI event message" or information/data contained in this message is then forwarded.

Alternatively or additionally, the communication module can be designed to detect at least one message sent by a component to a specific event to a specific bus address via the bus system as autonomously generated data, one of the specific bus address, the specific event and/or the to determine the message in a table associated network address and to send the message to the determined network address. This allows remote monitoring of components and/or control of external devices in the network.

According to the present invention, a lighting system has a bus system, a plurality of components coupled to the bus system and at least one of the communication modules described above.

According to the present invention, a method for transmitting data between at least one component coupled to a lighting bus system and a participant in a network based on an Internet protocol, in which the bus system is coupled to the network via an interface, each on the A unique bus address is assigned to the component coupled to the bus system, multiple network addresses are assigned to the interface and at least one of the multiple network addresses contains the bus address of a component, the steps:

- receiving from the interface data sent from the network to the at least one network address,

- extracting the bus address of the component from the network address,

- determining data to be sent to the component with the extracted bus address based on the received data and

- Transmission of the determined data to the component with the extracted bus address via the bus system

on.

Alternatively or additionally, at least one property of at least one component that can be queried in the bus system can represent a resource accessible via the network, which can be reached via a URL, wherein if the received data contain an http request for the resource from a network subscriber, in the method the following steps are carried out: - determining the property of the component associated with the requested resource in a table,

- receiving information from the component about the property requested in the data transfer,

- Generating a data packet with the received information,

- determining a network address for the transmission of the data based on the received data, and

- Sending the data packet to the determined network address.

The invention is explained in more detail below with reference to the accompanying drawings. Show it:

1 shows a lighting system according to a first exemplary embodiment according to the present invention,

Fig. 2 shows a simplified circuit of the communication module according to an embodiment according to the present invention,

3 is a schematic representation of a lighting system according to a second embodiment of the present invention, and

Figure 4 is a simplified diagram showing the method.

Components with the same functions are identified in the figures with the same reference symbols.

1 shows the possible structure of a lighting system according to the present invention. The system has a data bus 1, a large number of components 2a..2f connected to the data bus 1 and a communication module 4 connected to the data bus 1 and to a network 3 based on an Internet protocol.

The data bus 1 can be a bus system according to the DALI industry standard, via which the components 2a..2f, such as lighting operating devices, light sensors, motion sensors, buttons and control devices, control commands and operating data are transmitted. According to the DALI 2 standard, sensors such as brightness sensors and motion sensors no longer have to be queried by a control device to control lamp operating devices, but can send control commands to an operating device themselves, for example to switch on a lamp. So that the light can be switched off again with a button coupled to the data bus 1 and also assigned to the light without the button having to be pressed twice, the switch-on control command of the sensor or the operating status of the light can be sent to the button by means of a so-called "DALI event message". , ie a message about a specific event, are communicated via the data bus 1. In this way, the button can determine that the light is already on and should be switched off rather than switched on when the button is pressed.

The network 3 shown in FIG. 1 is a computer network in which payload data is sent in packets and in which, according to a layer model, control information from various network protocols is interleaved around the actual payload data in accordance with Internet Protocol Version 6 (IPv6).

A mobile control device 5 can be connected to the network 3 via a radio link and is used to query status and operating data of the components 2a..2f and to control at least some of the components 2a..2f. The control device 5 can be a smartphone, a personal digital assistant (PDA) or a tablet computer, which can be coupled to the network 3 via a mobile radio connection or a wireless local area network (WLAN) and on which the status and Operating data can be queried and displayed and control commands can be sent to the individual components 2a..2f. Alternatively, a non-mobile solution, e.g. a PC, is of course also conceivable.

With the network 3, a sensor 6 is connected, which can be located outside the building in which the data bus 1 is installed, and the control commands to at least one component 2a..2f via the network 3, the communication module 4 and sends the data bus 1. The sensor 6 can be a wind sensor that controls a drive of an awning as a component 2a..2f.

The communication module 4 can be a gateway and enables transparent transmission of the control commands and queries from the control unit 5 and the sensor 6 to the desired component 2a..2f. Transparent here means that at least some of the components 2a..2f can be addressed by the control unit 5 and the sensor 6 via network addresses according to the Internet Protocol Version 6 (IPv6), although within the data bus 1 each component 2a..2f only via its unique bus address/DALI address can be addressed.

According to the present invention, the communication module is a plurality of networks

assigned addresses, wherein at least one of the several network addresses contains the bus address (DALI address) of a component 2a..2f.

The control unit 5 and the sensor 6 send their requests and control commands to the communication module 4, which extracts the bus address of the components 2a..2f from the network address, and converts the requests and control commands into DALI-compliant requests and control commands, if necessary sends the components 2a..2f with the extracted bus address. In the case of queries, the communication module 4 can determine the network address of the control unit 5 or the sensor 6 from the data received from the control unit 5 or the sensor 6 and send the response to the query received via the data bus 1 to the determined network address. In this way, at least some of the components 2a..2f can be addressed by the control unit 5 and the sensor 6 like a network participant.

Fig. 2 shows a simplified circuit of the communication module 4 according to an embodiment according to the present invention. The communication module 4 shown in FIG. 2 has a network interface 7 which can be connected to the network 3 via a connection 8 , a bus interface 9 which can be connected to the data bus 1 , a control device 11 and a data memory 12 .

The controller 11 extracts the bus address and/or the queries or control commands from the data received from the network 3 via the network interface 7, converts the queries or control commands into DALI-compliant queries using a table stored in the data memory 12 and Control commands and sends them via the bus interface 9 to the component 2a..2f with the extracted bus address. The communication module 4 can be assigned its own unique bus address and the control device 11 can record the data transmitted via the data bus 1 by means of the bus interface 9 and forward certain data and/or data sent to certain bus addresses to the control unit 5 and/or the sensor 6. For this purpose, network addresses are stored in the data memory 12 for specific data or specific bus addresses or can be calculated automatically. Such forwarding can be commissioned by control unit 5 and/or sensor 6 .

In the example described, only a control device 5 and a sensor 6 are connected to the network or the communication module 4 . However, a large number of control devices 5, sensors 6 or other devices, such as actuators, switches or operating devices, can be connected to the network 3 or the communication module 4, even at the same time.

The queries or control commands can be contained in the data packets or the network address and/or already exist in a DALI-compliant manner, so that no conversion and no data memory 12 is necessary in order to be able to transmit them via the data bus 1. The graphical user interface can be DALI compliant or that of another control system.

According to the present invention, not only the components 2a..2f a unique identifier (URI) can be assigned in the network 3, but also their queryable or adjustable properties, so that these properties over the network 3 or the Internet Things (IoT) are available as resources/things and can be linked to other resources/things if necessary.

Fig. 3 shows a schematic representation of such a lighting system according to a second embodiment of the present invention. In the lighting system shown in Fig. 3, the communication module 4 connected to the network 4 (not shown) and the components 2a..2f are coupled to the data bus 1, the component 2a being a lamp "Lum 1" with the bus address s00, component 2b is a "Lum 2" lamp with bus address s01, component 2c is a twilight sensor "LS1" with bus address s10 and component 2d is a motion detector "PS1" with bus address s11.

In the lighting system, the properties of the components 2a .

The resources/things of the lighting system shown in FIG. 3 that are available on the network side in the Internet of Things (IldD) are specified to the right of the communication module 4 in a directory structure with the network address.

The resources “operating state”, “dimming value” and the settings “time” (dimming speed) and “color” (color temperature) are available for the light “Lum 1”. The network address "x:x:x:x::0" is assigned to the lamp "Lum 1", where the "0" corresponds to the bus address s00. The communication module 4 is a gateway to the partial network (subnet) "x:x:x :x::/64" of network 3 and can also have its own address on that subnet for configuration purposes.

The motion detector “PS1” can send the “DALI Event Message” described above to a specified bus address as a property, with the “DALI Event Message” being forwarded to a “Callback URL” in the IoT representation.

The specified properties and resources are of course only examples and following the same scheme further and/or other resources and properties can be defined.

4 shows a simplified diagram for representing the method, in which the method steps already explained above are shown again in a separate flowchart.

Claims (10)

Expectations 1. Communication module for connecting a lighting bus system (1) with a an internet protocol-based network (3), wherein each component (2a..2f) coupled to the bus system (1) is assigned a unique bus address, several network addresses are assigned to the communication module (4), at least one of the multiple network addresses contains the bus address of a component (2a..2f) and the communication module (4) is designed to receive data from the network (3) sent to the at least one network address, to extract the bus address of the component (2a..2f) from the network address, to the component (2a..2f) to determine data to be sent with the extracted bus address on the basis of the received data and to transmit the determined data to the component (2a..2f) with the extracted bus address via the bus system (1), or to transmit the data from a component (2a.. 2f) to make available to at least one network subscriber data that is generated autonomously and sent to the communication module (4) via the network (3). 2. The communication module as claimed in claim 1, wherein the communication module (4) is designed to extract the address of the component (2a..2f) from the interface identifier of the network address based on the Internet Protocol Version 6. 3. Communication module according to claim 2, wherein several components (2a..2f) in the bus system can be addressed using a group bus address and the communication module (4) is designed to assign the group bus address on the basis of a multicast address contained in the network address determine and carry out data transmission to the components (2a..2f) belonging to the determined group bus address on the basis of the received data. 4. Communication module according to one of claims 1 to 3, wherein the communication module (4) is designed to determine a control command from the received data and the determined control command to the component (2a..2f) with the extracted bus address or the components (2a..2f) with the determined group bus address. 5. Communication module according to one of claims 1 to 4, wherein the communication module (4) is designed to carry out a conversion of the data packet format of the received data into the data packet format of the bus system as a gateway that is transparent at least from the point of view of the network (3). 6. Communication module according to one of claims 1 to 5, wherein at least one property of at least one component (2a..2f) which can be queried in the bus system represents a resource which can be accessed via the network (3) and which can be accessed via a URL and the communication module (4) is designed to determine the property of the component (2a..2f) assigned to the requested resource in a translation table and to query the property in the data transmission when the received data contain a request from the resource. 7. Communication module according to claim 6, wherein the communication module (4) is designed to generate a data packet with information received from the component about the queried property, to determine a network address for the transmission of the data packet on the basis of the received data and the data packet to the determined network address. 8. Lighting system with a bus system, a plurality of components (2a..2f) coupled to the bus system (1) and the communication module (4) according to one of claims 1 to 7. 9. Method for transmitting data between at least one component (2a..2f) coupled to a lighting bus system (1) and a participant (5, 6) of a network (3) based on an Internet protocol, wherein the bus system (1) is coupled to the network (3) via an interface (4; 7..12), each component (2a..2f) coupled to the bus system (1) is assigned a unique bus address, several network addresses are assigned to the interface, at least one of the multiple network addresses contains the bus address of a component (2a..2f), and the method has the steps: receiving from the interface (4; 7..12) data sent from the network to the at least one network address, extracting the bus address of the component (2a..2f) from the network address, determining data to be sent to the component with the extracted bus address based on the received data and Transmission of the determined data to the component with the extracted bus address via the bus system. 10. The method of claim 9, wherein at least one property of at least one component (2a..2f) that can be queried in the bus system represents a resource that is accessible via the network (3) and can be reached via a URL, the received data contain a request for the resource from a network subscriber (5, 6), and the method has the steps: determining the property of the component (2a..2f) associated with the requested resource in a table, Receiving information about the property requested in the data transmission from the component (2a..2f), Generating a data packet with the received information, determining a network address for transmission of the data packet based on the received data, and Sending the data packet to the identified network address. 4 sheets of drawings